降水、灌溉和品种对玉米产量和水分利用效率的影响

8年田间试验结果表明,玉米产量明显受降水和灌溉的影响。玉米苗期灌溉最为关键,是保证高产的基础。在只灌溉苗水而没有其他灌溉条件下,夏玉米产量与7、8月份降水密切相关,而与生长季节的降水总量关系不明显。除了极干旱年份(季节降雨量小于200 mm)外,随着灌溉量增加,玉米水分利用效率(WUE)降低。玉米最优灌溉制度为:干旱年份,除了苗期的1次灌溉外,在拔节和扬花期分别实施2次灌溉;常年和湿润年份,除了出苗水外,在抽穗到扬花期的8月初实施1次灌溉。3年的田间试验结果表明,当地种植的不同玉米品种之间产量最大相差20%,水分利用效率差异在12%~19%。因此,将适宜的品种与优化的灌溉制度相结合,是提高华北平原夏玉米产量和水分利用效率的有效途径。     

基于回归等值线法的不同下垫面红壤水分时空变化规律研究

基于回归等值线法对百喜草覆盖、百喜草敷盖和对照处理的红壤水分时空变化进行了比较分析。结果显示,从年初到年终,随时间的推移,各处理各层土壤含水量均表现出"先减小,后增大"的趋势。在测定深度内,随土层深度增加,各处理各层土壤含水量却表现出"先增大,后减小"的趋势。百喜草覆盖处理,特别是上中层土壤含水量,随时间变化较大,与气候和百喜草生长密切相关,但随深度变化,层间土壤含水量变化较慢;百喜草敷盖和对照处理,土壤含水量受土层深度因素影响更明显。对于百喜草敷盖处理,随深度变化,层间土壤含水量变化较慢,但对于对照处理,随深度变化,层间土壤含水量变化较大。     

再生水灌溉利用区划研究

以北京市为例,在分析区域地形地貌特征、地表水功能分区、地下水防污性能等条件的基础上,制定北京市再生水灌溉利用分区,将北京市全境划分为禁止灌溉区、控制直接灌溉区和适宜直接灌溉区,得出再生水适宜直接灌溉区农田灌溉面积为9.33万hm2,再生水灌溉利用潜力为5.6亿m3。     

利用随机网络模型和CT数字图像预测近饱和土壤水分特征曲线

通过对连续土壤切片CT图像的分析,定量获取了土壤孔隙的大小分布情况。在此基础上建立了基于土壤孔隙形态学特征的随机网络模型,在孔隙尺度模拟了土壤中的水分运动过程,并预测了近饱和土壤水分特征曲线。结果表明,通过选取合适的模型参数,基于土壤孔隙形态学特征建立的随机网络模型可以模拟出与土壤样本实测值非常接近的水分特征曲线,可以作为一种快速测量的方法。     

水匮乏指数在区域水安全评价中的应用

针对水安全问题,以农垦红兴隆分局为例,采用水匮乏指数和样本均值-标准差分级法对红兴隆分局下属12个农场2006年的水安全状况进行了评价和分级,并根据分级结果提出了相应的对策。结果表明,八五三和红旗岭农场的WPI值处于安全状态,水安全状况最为乐观;饶河农场的WPI值处于较高安全状态,水安全状况较好;友谊、五九七、八五二、二九一和江川农场的WPI值处于中等安全状态,水安全保障体系有待于进一步加强;北兴农场的WPI值处于较低安全状态,水安全状况较差;而双鸭山、曙光和宝山农场的WPI值处于不安全状态,水安全状况最差。     

灌溉水矿化度及盐分带入量对小麦相对产量影响的统计分析

在搜集、统计大量咸水灌溉试验资料的基础上,选取咸水充分灌溉条件下矿化度和小麦产量的完整对应数据103组,统计分析了灌溉水矿化度及单位面积盐分带入量对小麦相对产量的影响,结果表明,随着灌溉水矿化度的增加,小麦相对产量呈线性递减趋势,当矿化度大于1.0 g/L时,灌溉水矿化度每增加1 g/L,小麦减产约5.6%;与矿化度类似,随着单位面积盐分带入量的增加,小麦的相对产量也线性降低,盐分带入量每增加1000 kg/hm2,小麦的产量将减少约2%。进一步的检验结果显示,应用灌溉水矿化度及单位面积盐分带入量均可较为可靠地估算小麦的相对产量,估算相对误差基本可控制在16%以内。     

膜下滴灌对加工番茄水分利用效率与品质的影响

在新疆石河子研究了膜下滴灌对加工番茄耗水特征、水分利用效率和品质的影响。结果表明,膜下滴灌处理番茄总耗水量较常规沟灌降低8.37%~59.33%,总耗水量也随滴灌量的增加而增加。膜下滴灌加工番茄耗水量以盛果期最高,开花座果期次之,成熟期和苗期最低,其日耗水强度表现出先升后降的变化趋势,总体低于常规沟灌处理。与常规沟灌相比,膜下滴灌能提高番茄果实硬度、可溶性固形物、番茄红素、Vc、可溶性酸和总糖含量以及糖酸比。从节水高产灌溉的角度考虑,当地加工番茄膜下滴灌量以6150 m3/hm2较为适宜。     

小麦实时控制灌溉的土壤水分含量探头合理埋设深度研究

利用室内控制试验研究了根据不同深度土壤水分传感器灌溉处理对冬小麦生物学性状及水分利用率等的影响。结果显示,以10 cm探头控制灌溉最为省水,同时冬小麦生物学性状及水分利用率等最佳。由于试验冬小麦处于生育前期,随着小麦生育期延伸,当根系超过30 cm深度时,根系吸水的深度增加,探头的埋设深度需要田间试验进行更详细的研究。     

C/N ratio control and substrate addition for periphyton development jointly enhance freshwater prawn Macrobrachium rosenbergii production in ponds

The present research investigated the effect of carbon/nitrogen ratio (C/N ratio) control in ponds with or without substrate addition for periphyton development on production of giant freshwater prawn. C/N ratios of 10, 15 and 20 were investigated in 40 m^− 2 ponds stocked with 2 prawn juveniles (5.023 ± 0.02 g) m^− 2 with or without added substrates for periphyton development. The various treatment combinations of C/N ratio and periphyton substrate addition are abbreviated as ‘CN10’, ‘CN15’, ‘CN20’, ‘CN10 + P’, ‘CN15 + P’ and ‘CN20 + P’, P representing periphyton substrate. A locally formulated and prepared feed containing 30% crude protein with C/N ratio10 was applied. Tapioca starch was used as carbohydrate source for manipulating C/N ratio and applied to the water column separately from the feed. Increasing the C/N ratio from 10 to 20 reduced (P < 0.001) the total ammonia-nitrogen (TAN), nitrite–nitrogen (NO₂–N) and nitrate–nitrogen (NO₃–N) in water column and total Kjeldahl nitrogen (TKN) in sediment. The addition of substrates only influenced the NO₂–N concentration in the water column (P < 0.001). Increasing the C/N ratio raised the total heterotrophic bacterial (THB) population in the water column, sediment and periphyton (P < 0.001). It also increased the dry matter (DM), ash free dry matter (AFDM), and chlorophyll a content of periphyton (P < 0.001). The lowest specific growth rate (SGR), the highest food conversion ratio (FCR), and the lowest protein efficiency ratio (PER) were recorded in treatment CN10 (P < 0.05). The addition of substrates did not influence size at harvest (P > 0.05) but improved the survival from 62.8 to 72% (P < 0.001). Increasing the C/N ratio from 10 to 20 increased the net yield by 40% and addition of substrate increased the net yield by 23%. The combination of C/N ratio control and substrate addition increased the net yield by 75% from 309 (CN10) to 540 (CN20 + P) kg ha^− 1 (120 days)^− 1. This 75% higher production concurred with (1) a lower inorganic nitrogen content in the water column, (2) a higher THB abundance supplying additional single cell protein to augment the prawn production, and (3) an improved periphyton productivity and quality.     

Outdoor mass microalgae production in Bahia Kino, Sonora, NW Mexico

The diatom Chaetoceros muelleri was grown in outdoor mass cultures under the winter, spring and summer conditions of Bahia Kino, Sonora, NW Mexico. The solar irradiance in winter was close to 60% of that available in spring and summer, but the cell concentrations and the harvestable biomass were one order of magnitude higher in spring and summer than in winter. There was no difference between the biomass harvested after 2 and 3 days in winter and summer, whereas in spring it was higher after 3 days. The protein content was significantly lower in winter, and carbohydrates and lipids were higher in winter and spring. The number of cells and the amount of harvestable biomass of outdoor cultures of C. muelleri depend on the temperature prevailing in each season, which causes significant differences in growth rates and in biochemical composition.